The <i>O</i>‐methyltransferase <scp>PMT</scp>2 mediates methylation of pinosylvin in Scots pine

Paasela, Tanja; Lim, Kean‐Jin; Pietiäinen, Milla; Teeri, Teemu H.

doi:10.1111/nph.14480

Cited by 25 publications

(20 citation statements)

References 52 publications

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“…However, it should be noted that PsPMT1 showed a relatively broad substrate specificity, methylating several compounds such as stilbene aglycones, flavonoids, and hydroxycinnamic acids, many of these even more efficiently than pinosylvin. In 2017, Paasela and co-workers [134] subsequently isolated and characterized an O-methyltransferase from P. sylvestris (PpPMT2), which is held responsible for the methylation of pinosylvin. Unlike the multifunctional PsPMT1, PsPMT2 preferentially methylated pinosylvin into its monomethyl ether, showing a high degree of specificity for stilbenes.…”

Section: Methylationmentioning

confidence: 99%

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Impact of Environmental Factors on Stilbene Biosynthesis

Valletta

Iozia

Leonelli

2021

Plants

104

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Stilbenes are a small family of polyphenolic secondary metabolites that can be found in several distantly related plant species. These compounds act as phytoalexins, playing a crucial role in plant defense against phytopathogens, as well as being involved in the adaptation of plants to abiotic environmental factors. Among stilbenes, trans-resveratrol is certainly the most popular and extensively studied for its health properties. In recent years, an increasing number of stilbene compounds were subjected to investigations concerning their bioactivity. This review presents the most updated knowledge of the stilbene biosynthetic pathway, also focusing on the role of several environmental factors in eliciting stilbenes biosynthesis. The effects of ultraviolet radiation, visible light, ultrasonication, mechanical stress, salt stress, drought, temperature, ozone, and biotic stress are reviewed in the context of enhancing stilbene biosynthesis, both in planta and in plant cell and organ cultures. This knowledge may shed some light on stilbene biological roles and represents a useful tool to increase the accumulation of these valuable compounds.

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Section: Methylationmentioning

confidence: 99%

“…Several studies on Scots pine have shown remarkable increases in pinosylvin and pinosylvin monomethyl ether accumulation following wounding stress, associated with overexpression of PsSTS, as well as of genes coding for O-methyltransferases involved in stilbene methylation (PsMT1 and PsMT2) [134,221,223].…”

Section: Woundingmentioning

confidence: 99%

Impact of Environmental Factors on Stilbene Biosynthesis

Valletta

Iozia

Leonelli

2021

Plants

104

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“… Chaffey (2002) asked ‘Why is there so little research into the cell biology of the secondary vascular system of trees?’ and addressed the lack of funding, techniques and the imparity between primary and secondary cell wall research. Heartwood extractives have been mainly investigated by wet-chemical and chromatographic methods ( Ekeberg et al 2006 ) and recently also genetic approaches ( Paasela et al 2017 ). To investigate extractives in context with microstructure, TOF-SIMS imaging has been applied in Cryptomeria japonica trees and showed that the extractives tend to accumulate near the radial rays ( Saito et al 2008 , Kuroda et al 2014 ).…”

Section: Introductionmentioning

confidence: 99%

Antifungal stilbene impregnation: transport and distribution on the micron-level

et al. 2018

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The transition from the living water-transporting sapwood to heartwood involves in many tree species impregnation with extractives. These differ in amount and composition, and enhance resistance against bacteria, insects or fungi. To understand the synthesis, transport and impregnation processes new insights into the biochemical processes are needed by in-situ methods. Here we show the extractive distribution in pine (Pinus sylvestris) microsections with a high lateral resolution sampled in a non-destructive manner using Confocal Raman Microscopy. Integrating marker bands of stilbenes and lipids enables to clearly track the rapid change from sapwood to heartwood within one tree ring. The higher impregnation of the cell corner, compound middle lamella, the S3 layer and pits reveals the optimization of decay resistance on the micron-level. Furthermore, deposits with changing chemical composition are elucidated in the rays and lumen of the tracheids. The spectral signature of these deposits shows the co-location of lipids and pinosylvins with changing ratios from the living to the dead tissue. The results demonstrate that the extractive impregnation on the micro- and nano-level is optimized by a symbiotic relationship of lipids and pinosylvins to enhance the tree’s resistance and lifetime.

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“…The mapping and bioinformatic analyses of gene expression are based on the most complete and high-quality reference transcriptome of P. sylvestris available to date (Ojeda et al 2019). Previous transcriptome studies of P. sylvestris have concentrated on a narrow set of tissues in each study such as wood (Paasela et al 2017), embryo (Merino et al 2016), and needles (Wachowiak et al 2015; Duarte et al 2019) or focused on a limited set of genes (Guseva et al 2020). The present study allows comparison across a wide set of genes expressed in the above-ground parts of adult P. sylvestris trees growing in a natural forest.…”

Section: Resultsmentioning

confidence: 99%

Atlas of tissue-specific and tissue-preferential gene expression in ecologically and economically significant coniferPinus sylvestris

Cervantes

Vuosku

Paczesniak

et al. 2020

Preprint

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Background: Despite their ecological and economical importance, conifers still have limited genomic resources, mainly due to the large size and complexity of their genomes. In addition, several of the available genomic resources lack complete structural and functional annotation. Transcriptomic resources have been commonly used to compensate for these deficiencies, though for most conifer species the currently available transcriptomes are limited to a small number of tissues, or capture only a fraction of the genes present in the genome. Results: Here we provide an atlas of gene expression patterns for conifer Pinus sylvestris grown under natural conditions across five tissues: embryo, megagametophyte, needle, phloem, and vegetative bud. Compared to previous studies, we used a wider range of tissues and focused our analyses on the expression profiles of genes at tissue level. We provide comprehensive information of the per-tissue normalized expression level, and indication of tissue preferential upregulation or tissue preferential expression. We identified a total of 48,001 tissue preferentially upregulated and tissue specifically expressed genes, of which 28% have annotation in the Swiss-Prot database. The annotated genes were associated with a total of 84,498 GO terms, of which 1,834 had significant enrichment in different processes and functions, for example glyoxylate cycle in megagametophyte and defense response in needle. Even though most of the genes originating from the transcriptome do not have functional information in current biological databases, the tissue-specific patterns identified here provide valuable information about their potential functions for further studies. Conclusions: The genes identified in this study will contribute to improve the annotation of the already available and forthcoming conifer genomes. This atlas of gene expression also provides ground to further the research in the areas of plant physiology, population genetics, and genomics in general. As we provide information on tissue specificity at both diploid and haploid life stages, our data will also contribute to the understanding of evolutionary rates of different tissue types and ploidy levels.

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The O‐methyltransferase PMT2 mediates methylation of pinosylvin in Scots pine

Cited by 25 publications

References 52 publications

Impact of Environmental Factors on Stilbene Biosynthesis

Impact of Environmental Factors on Stilbene Biosynthesis

Antifungal stilbene impregnation: transport and distribution on the micron-level

Atlas of tissue-specific and tissue-preferential gene expression in ecologically and economically significant coniferPinus sylvestris

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